Article ID: | iaor20141726 |
Volume: | 270 |
Issue: | 6 |
Start Page Number: | 330 |
End Page Number: | 342 |
Publication Date: | Nov 2014 |
Journal: | Journal of Computational and Applied Mathematics |
Authors: | Lger Raphal, Viquerat Jonathan, Durochat Clment, Scheid Claire, Lanteri Stphane |
Keywords: | engineering |
The present work is about the development of a parallel non‐conforming multi‐element discontinuous Galerkin time‐domain (DGTD) method for the simulation of the scattering of electromagnetic waves by metallic nanoparticles. Such nanoparticles most often have curvilinear shapes, therefore we propose a numerical modeling strategy which combines the use of an unstructured tetrahedral mesh for the discretization of the scattering structures with a structured (uniform cartesian) mesh for treating efficiently the rest of the domain. The overall goal is to increase the flexibility in the meshing process while decreasing the needs in computational resources for the target applications. The latter are here modeled by the system of 3D time‐domain Maxwell equations coupled to a Drude dispersion model for taking into account the material properties of nanoparticles at optical frequencies. We propose an auxiliary differential equation (ADE) based DGTD method for solving the resulting system and present numerical results demonstrating the benefits of using non‐conforming multi‐element meshes in this particular application context.